BACKGROUND OF THE INVENTION
1. Field of the Invention
[0001] The invention relates to an exhaust gas control apparatus for an internal combustion
engine and a control method for the same.
2. Description of Related Art
[0002] As described in Japanese Patent Application Publication No.
2007-23792 (
JP-2007-23792 A), there is known an apparatus that includes a filter that collects particulate matter
(PM) in exhaust gas, as an exhaust gas control apparatus that is provided in an exhaust
passage of an internal combustion engine. In this exhaust gas control apparatus, as
the amount of the PM collected by the filter increases, the pressure loss of the filter
increases to adversely affect the output of the engine, and the like. Thus, a so-called
recovery process for burning the collected PM by raising the temperature of the filter
is carried out.
[0003] In this recovery process, when the amount of the PM deposited in the filter reaches
a preset amount, an addition agent such as fuel is supplied to the exhaust passage.
Then, the filter is heated up due to the combustion of the addition agent, and the
oxidation of the PM in the filter is thereby promoted. As a result, the amount of
the PM deposited in the filter decreases to a prescribed amount.
[0004] In the apparatus that carries out the recovery process as described above, a PM discharge
amount per unit time and a PM oxidation amount per unit time are calculated to estimate
a PM deposition amount in the filter.
[0005] As described in the aforementioned Japanese Patent Application Publication No.
2007-23792 (
JP-2007-23792 A), ashes, which are components originating from lubricating oil and are difficult
to burn through the aforementioned recovery process, are deposited in the filter.
When these ashes are deposited in the filter, the oxidation speed of PM changes. Therefore,
if the oxidation speed of the PM is calculated without taking the influence of the
ashes into account, the accuracy of the oxidation speed becomes low. As a result,
the accuracy in estimating the PM deposition amount in the filter decreases. When
the accuracy in estimating the PM deposition amount thus decreases, burned embers
of the PM may remain, for example, when the recovery process is completed.
SUMMARY OF THE INVENTION
[0006] This invention provides an exhaust gas control apparatus for an internal combustion
engine and a control method for the same, which make it possible to more accurately
calculate a PM oxidation speed in a filter.
[0007] A first aspect of the invention relates an exhaust gas control apparatus for an internal
combustion engine. The exhaust gas control apparatus includes a filter that collects
particulate matter in exhaust gas; and a control device that performs a recovery process
for the filter. The control device calculates an oxidation speed of the particulate
matter in the filter on a basis of a thickness of ashes deposited in the filter.
[0008] The inventor has found that the oxidation speed of the particulate matter in the
filter, namely, a PM oxidation speed is more greatly affected by the thickness of
the ashes deposited in the filter than by the deposition amount of the ashes in the
filter. For example, in the case where the density of the ashes (the mass of the ashes
per unit volume) is small and the thickness of the deposited ashes is large, the PM
oxidation speed decreases even if the deposition amount itself of the ashes is small.
[0009] Thus, in this configuration, the oxidation speed of the particulate matter is calculated
on the basis of the thickness of the ashes deposited in the filter, and the PM oxidation
speed in the filter can be accurately calculated.
[0010] The inventor has confirmed that the actual PM oxidation speed decreases as the thickness
of the ashes deposited in the filter increases. Thus, in the foregoing aspect of the
invention, the control device may calculate the oxidation speed in a manner such that
the oxidation speed is decreased as the thickness of the ashes deposited in the filter
increases. By adopting this configuration, the PM oxidation speed can be suitably
calculated on the basis of the thickness of the ashes.
[0011] In the exhaust gas control apparatus according to the foregoing aspect of the invention,
the control device may calculate the thickness of the ashes deposited in the filter
by calculating a deposition amount of the ashes in the filter, calculating a deposition
density of the ashes on a basis of a maximum flow rate of exhaust gas, and dividing
the deposition amount by a value that is obtained by multiplying a collection area
of the filter by the deposition density.
[0012] The ashes deposited in the filter are compressed due to the impetus of flowing exhaust
gas. Thus, the density of the ashes deposited in the filter, namely, the deposition
density of the ashes can be calculated on the basis of the maximum flow rate of exhaust
gas. Thus, in this configuration, the deposition density of the ashes is calculated
on the basis of the maximum flow rate of exhaust gas. Then, the deposition amount
of the ashes is divided by the value that is obtained by multiplying the deposition
density by the collection area of the filter. Thus, the thickness of the ashes deposited
in the filter can be calculated.
[0013] It should be noted that the deposition amount of ashes can be estimated from a difference
between an exhaust gas pressure upstream of the filter and an exhaust gas pressure
downstream of the filter after the completion of the recovery process, a consumption
amount of a lubricating oil for the engine, or an operation time of the internal combustion
engine, a running distance of the vehicle, or the like, which is correlated with the
consumption amount of the lubricating oil for the engine.
[0014] In the exhaust gas control apparatus according to the foregoing aspect of the invention,
the control device may calculate a wall surface deposition amount that is an amount
of ashes deposited on a wall surface of the filter in a radial direction of the filter,
as the deposition amount of the ashes, and may set a collection area of the filter
in the radial direction of the filter, as the collection area.
[0015] In the filter, ashes are deposited on the wall surface of the filter in the radial
direction of the filter (that is, the wall surface of the filter in a sectional view
of the filter taken along the radial direction of the filter), and on a bottom face
of the filter that is located in a downstream side portion of the filter with respect
to the flow of exhaust gas. It should be noted herein that since a larger amount of
PM is collected on the wall surface of the filter in the radial direction of the filter
than on the bottom face of the filter that is located in the downstream side portion
of the filter with respect to the flow of exhaust gas, it is desirable to accurately
calculate the PM oxidation speed on the wall surface of the filter.
[0016] In this respect, according to this configuration, the wall surface deposition amount,
which is the amount of the ashes deposited on the wall surface of the filter in the
radial direction of the filter, is calculated, and the collection area of the filter
in the radial direction of the filter (that is, the collection area on the wall surface
of the filter in the radial direction of the filter) is set as the collection area.
Thus, the thickness of the ashes deposited on the wall surface of the filter in the
radial direction of the filter can be calculated. Then, the PM oxidation speed is
calculated on the basis of the thickness of the ashes deposited on the wall surface
of the filter in the radial direction of the filter. Therefore, the PM oxidation speed
on the wall surface of the filter in the radial direction of the filter can be accurately
calculated.
[0017] In the exhaust gas control apparatus according to the foregoing aspect of the invention,
the control device may calculate the wall surface deposition amount in a manner such
that the wall surface deposition amount is decreased as a fluctuation amount of an
exhaust gas flow rate increases.
[0018] The ashes deposited on the wall surface of the filter in the radial direction of
the filter are separated from the wall surface due to fluctuations in the exhaust
gas flow rate, and are collected again on the bottom face of the filter that is located
in the downstream side portion of the filter with respect to the flow of exhaust gas.
Accordingly, as the fluctuation amount of the exhaust gas flow rate increases, the
amount of the ashes separated from the wall surface of the filter in the radial direction
of the filter increases, and the deposition amount of the ashes remaining on the wall
surface decreases. Thus, in this configuration, the wall surface deposition amount
of the ashes is calculated to decrease as the fluctuation amount of the exhaust gas
flow rate increases. Accordingly, the wall surface deposition amount of the ashes
can be appropriately estimated.
[0019] In the exhaust gas control apparatus according to the foregoing aspect of the invention,
the control device may measure the number of times that a fluctuation amount of an
exhaust gas flow rate becomes larger than a predetermined value, and may calculate
the wall surface deposition amount in a manner such that the wall surface deposition
amount is decreased as the measured number of times increases.
[0020] As described above, the ashes deposited on the wall surface of the filter in the
radial direction of the filter are separated from the wall surface due to fluctuations
in the exhaust gas flow rate, and are collected again on the bottom face of the filter
that is located in the downstream side portion with respect to the flow of exhaust
gas. Accordingly, as the number of times of fluctuation in the exhaust gas flow rate
increases, the amount of the ashes separated from the wall surface of the filter in
the radial direction of the filter increases, and the deposition amount of the ashes
remaining on the wall surface decreases. Thus, in this configuration, the number of
times that the fluctuation amount of the exhaust gas flow rate becomes larger than
the predetermined value is measured, and the wall surface deposition amount of the
ashes is calculated to decrease as the measured number of times increases. Accordingly,
with this configuration as well, the wall surface deposition amount of the ashes can
be appropriately estimated.
[0021] In the exhaust gas control apparatus according to the foregoing aspect of the invention,
in order to calculate the wall surface deposition amount of ashes, the control device
may calculate a ratio of the amount of the ashes deposited on the wall surface to
a total deposition amount of the ashes in the filter, and may calculate the wall surface
deposition amount on a basis of the calculated ratio. It should be noted that, in
this configuration, the total deposition amount of the ashes can be estimated from
a difference between an exhaust gas pressure upstream of the filter and an exhaust
gas pressure downstream of the filter after the completion of the recovery process,
a consumption amount of a lubricating oil for the engine, or an operation time of
the internal combustion engine, a running distance of the vehicle, or the like, which
is correlated with the consumption amount of the lubricating oil for the engine. Further,
the ratio of the deposition amount of the ashes on the wall surface can be set on
the basis of the aforementioned fluctuation amount of the exhaust gas flow rate or
the aforementioned number of times of fluctuation in the exhaust gas flow rate.
[0022] A second aspect of the invention relates to a control method for an exhaust gas control
apparatus for an internal combustion engine, the exhaust gas control apparatus including
a filter that collects particulate matter in exhaust gas. The control method includes
calculating an oxidation speed of the particulate matter in the filter on a basis
of a thickness of ashes deposited in the filter; and performing a recovery process
for the filter using the calculated oxidation speed.
BRIEF DESCRIPTION OF THE DRAWINGS
[0023] Features, advantages, and technical and industrial significance of an exemplary embodiment
of the invention will be described below with reference to the accompanying drawings,
in which like numerals denote like elements, and wherein:
FIG. 1 is a schematic diagram showing an internal combustion engine to which an exhaust
gas control apparatus for an internal combustion engine according to an embodiment
of the invention is applied, and a peripheral configuration of the internal combustion
engine and the exhaust gas control apparatus;
FIG. 2 is a graph showing a relationship between an engine rotational speed and a
PM discharge amount, and a relationship between a fuel injection amount and the PM
discharge amount;
FIG. 3 is a flowchart showing a procedure of a processing of calculating a PM oxidation
speed;
FIG. 4 is a graph showing a relationship between a maximum flow rate of exhaust gas
and a deposition density of ashes;
FIG. 5 is a graph showing a relationship between a fluctuation amount of an exhaust
gas flow rate and a wall surface deposition ratio, and a relationship between the
number of times of fluctuation in the exhaust gas flow rate and the wall surface deposition
ratio; and
FIG. 6 is a graph showing a relationship among a bed temperature of a filter, a thickness
of the ashes, and the PM oxidation speed.
DETAILED DESCRIPTION OF EMBODIMENT
[0024] Hereinafter, an exhaust gas control apparatus for an internal combustion engine according
to an embodiment of this invention will be described with reference to FIGS. 1 to
6. FIG. 1 is a schematic diagram showing a diesel engine (hereinafter referred to
simply as "an engine") to which the exhaust gas control apparatus according to this
embodiment of the invention is applied, and a peripheral configuration of the engine
and the exhaust gas control apparatus.
[0025] The engine 1 is provided with a plurality of cylinders #1 to #4. A cylinder head
2 is provided with a plurality of fuel injection valves 4a to 4d. These fuel injection
valves 4a to 4d inject fuel into combustion chambers of the cylinders #1 to #4 respectively.
Further, in the cylinder head 2, intake ports for introducing fresh air into the cylinders,
and exhaust ports 6a to 6d for discharging combustion gas to the outside of the cylinders
are provided for the cylinders #1 to #4 respectively.
[0026] The fuel injection valves 4a to 4d are connected to a common rail 9 in which high-pressure
fuel is accumulated. The common rail 9 is connected to a supply pump 10. The supply
pump 10 sucks in fuel in a fuel tank, and supplies high-pressure fuel to the common
rail 9. The high-pressure fuel supplied to the common rail 9 is injected from the
fuel injection valves 4a to 4d into the cylinders respectively, when the fuel injection
valves 4a to 4d are opened.
[0027] An intake manifold 7 is connected to the intake ports. The intake manifold 7 is connected
to an intake passage 3. An intake throttle valve 16 for adjusting the amount of intake
air is provided in this intake passage 3.
[0028] An exhaust manifold 8 is connected to the exhaust ports 6a to 6d. The exhaust manifold
8 is connected to an exhaust passage 26. A turbocharger 11 that supercharges intake
air introduced into the cylinders with the aid of an exhaust gas pressure is provided
in the exhaust passage 26. An intercooler 18 is provided in the intake passage 3 at
a position between an intake-side compressor of the turbocharger 11 and the intake
throttle valve 16. This intercooler 18 cools the intake air whose temperature has
risen through the supercharging by the turbocharger 11.
[0029] Further, in the exhaust passage 26, a converter 30 that purifies exhaust gas components
is provided downstream of an exhaust-side turbine of the turbocharger 11. An oxidation
catalyst 31 and a filter 32 are disposed in series with respect to the flow direction
of exhaust gas, inside this converter 30.
[0030] A catalyst that subjects HC in exhaust gas to an oxidation treatment is supported
in the oxidation catalyst 31. Further, the filter 32 is a member that collects particulate
matter (PM) in exhaust gas, and is constituted by a porous ceramic. A catalyst for
promoting the oxidation of PM is supported in this filter 32. The PM in exhaust gas
is collected when passing through a porous wall of the filter 32.
[0031] Further, the cylinder head 2 is provided with a fuel addition valve 5 for supplying
the oxidation catalyst 31 and the filter 32 with fuel as an addition agent. This fuel
addition valve 5 is connected to the supply pump 10 via a fuel supply pipe 27, and
fuel is injected from the fuel addition valve 5 toward the interior of the exhaust
port 6d of the fourth cylinder #4. This injected fuel reaches the oxidation catalyst
31 and the filter 32 together with exhaust gas. It should be noted that the position
at which the fuel addition valve 5 is disposed can be appropriately changed as long
as the fuel addition valve 5 is located upstream of the converter 30 in an exhaust
system.
[0032] In addition, the engine 1 is equipped with an exhaust gas recirculation device (hereinafter
referred to as an EGR device). This EGR device is a device that introduces part of
exhaust gas into intake air to lower the combustion temperature in the cylinders and
hence reduce the generation amount of NOx. This exhaust gas recirculation device includes
an EGR passage 13 as an exhaust gas recirculation passage through which the intake
passage 3 and an exhaust passage (an exhaust manifold 8) communicate with each other,
an EGR valve 15 that is provided in the EGR passage 13 to function as a flow rate
control valve, an EGR cooler 14, and the like. Through the adjustment of the opening
degree of the EGR valve 15, the recirculation amount of the exhaust gas introduced
from the exhaust passage 26 into the intake passage 3, namely, an EGR amount is regulated.
Further, the EGR cooler 14 lowers the temperature of the exhaust gas flowing in the
EGR passage 13.
[0033] The engine 1 is provided with various sensors for detecting an engine operation state.
For example, an airflow meter 19 detects an intake air amount GA in the intake passage
3. A throttle valve opening degree sensor 20 detects an opening degree of the intake
throttle valve 16. An exhaust gas temperature sensor 33, which is provided downstream
of the oxidation catalyst 31 with respect to the flow of exhaust gas, measures an
exhaust gas temperature TE that is a temperature of the exhaust gas that has just
passed through the oxidation catalyst 31. A differential pressure sensor 34 detects
a pressure difference ΔP between an exhaust gas pressure upstream of the filter 32
with respect to the flow of exhaust gas and an exhaust gas pressure downstream of
the filter 32 with respect to the flow of exhaust gas. An engine rotational speed
sensor 23 detects a rotational speed of a crankshaft, namely, an engine rotational
speed NE. An accelerator sensor 24 detects a depression amount of an accelerator pedal,
namely, an accelerator operation amount ACCP.
[0034] Outputs of these various sensors are input to a control device 25. This control device
25 mainly includes a microcomputer that includes a central processing unit (a CPU),
a read only memory (a ROM) in which various programs, maps and the like are stored
in advance, a random access memory (a RAM) that temporarily stores a calculation result
of the CPU or the like, a timer counter, an input interface, an output interface,
and the like.
[0035] This control device 25 performs various kinds of control for the engine 1, for example,
fuel injection amount control and fuel injection timing control for the fuel injection
valves 4a to 4d and the fuel addition valve 5, discharge pressure control for the
supply pump 10, drive amount control for an actuator 17 that opens/closes the intake
throttle valve 16, opening degree control for the EGR valve 15, and the like. Further,
the control device 25 performs various kinds of exhaust gas control, such as a recovery
process for a filter that causes the PM collected by the aforementioned filter 32
to burn.
[0036] The recovery process for the aforementioned filter 32 is basically carried out as
follows. First, a PM discharge amount PMe, which is an amount of the PM that is discharged
from all the combustion chambers of the engine 1, is calculated on the basis of a
map that is set through an experiment conducted in advance or the like, for example,
a PM discharge amount calculation map as shown in FIG. 2, which uses a fuel injection
amount Q of the fuel injection valves 4a to 4d and then engine rotational speed NE
as parameters. It should be noted that, as shown in FIG. 2, the PM discharge amount
PMe is calculated to increase as the engine rotational speed NE increases or as the
fuel injection amount Q increases. This PM discharge amount PMe is repeatedly calculated
on a predetermined cycle, and an accumulated value of the PM discharge amount PMe
is calculated. Thus, a PM deposition amount PMsm, which is an amount of the PM deposited
in the filter 32, is estimated.
[0037] Then, when the PM deposition amount PMsm thus calculated reaches a recovery start
value PMstart, the recovery process for the filter 32 is started. In this recovery
process, fuel is added by the aforementioned fuel addition valve 5. The fuel injected
from this fuel addition valve 5 is burned upon reaching the oxidation catalyst 31,
so that the temperature of exhaust gas is raised. Then, the exhaust gas heated up
in the oxidation catalyst 31 flows into the filter 32, so that the filter 32 is heated
up. Thus, the PM deposited in the filter 32 is subjected to an oxidation treatment
to recover the filter 32.
[0038] A decrease amount of the PM resulting from the heat-up of the filter 32, namely,
a PM deposition amount PMsm during recovery of the filter 32 is estimated on the basis
of an expression (1) shown below.

In the expression (1), PMsm denotes a PM deposition amount, PMe denotes a PM discharge
amount, and PMc denotes a PM oxidation amount. The aforementioned PM oxidation amount
PMc is an amount of the PM that is collected by the filter 32 and subjected to a combustion
treatment. This PM oxidation amount PMc is calculated on the basis of a map that is
set through an experiment conducted in advance or the like, for example, an oxidation
speed map that indicates an oxidation amount of PM per unit time, or the like. The
PM oxidation amount PMc and the PM discharge amount PMe are repeatedly calculated
on a predetermined cycle, and the PM disposition amount PMsm is calculated according
to the aforementioned expression (1) in synchronization with the calculation of those
amounts. Thus, the PM deposition amount PMsm during the recovery process is estimated.
[0039] When the PM deposition amount PMsm during the recovery process, which is thus estimated,
becomes small enough to fall below a predetermined recovery end value PMf, the recovery
process for the filter 32 is ended. Thus, the PM deposition amount PMsm in the filter
32 is reduced to a prescribed amount equivalent to the recovery end value PMf.
[0040] Ashes, which are components originating from lubricating oil and are difficult to
burn through the aforementioned recovery process, are deposited in the filter 32.
It should be noted that components contained in an addition agent and the like for
lubricating oil (metal components such as Zn, Ca, Mg, Na and the like) can be mentioned
as examples of these ashes. When these ashes are deposited in the filter 32, a PM
oxidation speed PMcs changes. Therefore, when the PM oxidation speed PMcs is calculated
without taking the influence of the ashes into account, the accuracy of the oxidation
speed becomes low. That is, the discrepancy between an actual PM oxidation speed and
the PM oxidation speed PMcs obtained from the aforementioned oxidation speed map increases.
When the accuracy of the PM oxidation speed PMcs thus becomes low, the accuracy in
estimating the PM deposition amount PMsm in the filter 32 decreases. When the accuracy
in estimating the PM deposition amount PMsm thus decreases, the recovery process is
completed before the recovery end value PMf is reached. As a result, there may remain
burned embers of the PM when the recovery process is completed.
[0041] In this situation, the inventor has found that the oxidation speed of the particulate
matter in the filter 32, namely, the PM oxidation speed PMcs is more greatly affected
by the thickness of the ashes deposited in the filter 32 than by the deposition amount
of the ashes in the filter 32. More specifically, the inventor has found that the
actual PM oxidation speed decreases as the thickness of the ashes deposited in the
filter 32 increases. It is considered that the reason for the occurrence of this phenomenon
is as follows. That is, it is considered that as the thickness of the ashes increases,
the area of contact between the catalyst supported in the filter 32 and the PM decreases,
the catalytic action decreases, and hence the oxidation speed of the,PM decreases.
[0042] Thus, in this embodiment of the invention, the PM oxidation speed PMcs is calculated
on the basis of a thickness At of the ashes deposited in the filter 32, so that the
PM oxidation speed PMcs is more accurately calculated.
[0043] FIG. 3 shows a procedure of a processing of calculating the PM oxidation speed PMcs
in this embodiment of the invention. It should be noted that this processing is repeatedly
performed by the control device 25 on a predetermined cycle. When this processing
is started, a current ash deposition amount Asm is calculated (S100). In this case,
the ash deposition amount Asm is calculated as follows. That is, as the deposition
amount of ashes increases in the filter 32, the pressure difference ΔP detected by
the differential pressure sensor 34 increases. Accordingly, the ash deposition amount
Asm is estimated on the basis of the pressure difference ΔP.
[0044] Subsequently, the ashes deposited in the filter 32 are compressed due to impetus
of flowing exhaust gas. Therefore, the density of the ashes deposited in the filter
32, namely, a deposition density Ad can be calculated on the basis of a maximum flow
rate of exhaust gas. Thus, in step S200 that follows step S100, the deposition density
Ad, which is the density of the ashes deposited in the filter 32, is calculated on
the basis of a maximum flow rate EXmax of exhaust gas during the operation of the
engine (S200). In this step S200, as shown in FIG. 4, this deposition density Ad is
calculated to increase as the maximum flow rate EXmax of exhaust gas increases. It
should be noted that the maximum flow rate EXmax of exhaust gas is a maximum value
of the flow rate of exhaust gas during the operation of the engine, and is updated
as needed during the operation of the engine. Further, the flow rate of exhaust gas
is estimated on the basis of an intake air amount, an engine load, an engine rotational
speed, and the like.
[0045] Subsequently, a wall surface deposition ratio R of the ashes is calculated on the
basis of a fluctuation amount EXh of the exhaust gas flow rate and the number N of
times of fluctuation in the exhaust gas flow rate (S300). The fluctuation amount EXh
is an absolute value of a difference between a maximum value of the exhaust gas flow
rate and a minimum value of the exhaust gas flow rate. Further, the number N of times
of fluctuation is the number of times of fluctuation in the exhaust gas flow rate,
more specifically, the number of times that the aforementioned fluctuation amount
EXh becomes larger than a predetermined value. This fluctuation amount EXh and this
number N of times of fluctuation are measured during the recovery process for the
filter 32 and are stored in a storage unit of the control device 25, and are read
from the storage unit of the control device 25 when the present processing is performed.
The wall surface deposition ratio R of the ashes is a ratio of a wall surface deposition
amount as an amount of the ashes deposited on a wall surface of the filter 32 in a
radial direction of the filter 32 (that is, the wall surface of the filter 32 in a
sectional view of the filter 32 taken along the radial direction of the filter 32,
in other words, the wall surface extending in an axial direction of the filter 32)
to a total deposition amount of the ashes in the filter 32 (the aforementioned ash
deposition amount Asm). A value between "0" and "1" is set as this wall surface deposition
ratio R. In the case where all the ashes are deposited on a bottom face of the filter
32, the wall surface deposition ratio R is set equal to "0". Further, in the case
where all the ashes are deposited on the wall surface of the filter 32 in the radial
direction of the filter 32, the wall surface deposition ratio R is set equal to "1".
[0046] The process of step S300 is performed for the following reason. In the filter 32,
first, ashes are deposited on the wall surface of the filter 32 in the radial direction
of the filter 32 and on the bottom face of the filter 32 that is located in a downstream
side portion of the filter 32 with respect to the flow of exhaust gas. It should be
noted herein that since a larger amount of PM is collected on the wall surface of
the filter 32 in the radial direction of the filter 32 than on the bottom face of
the filter 32 that is located in the downstream side portion of the filter 32 with
respect to the flow of exhaust gas, it is desirable to accurately calculate the PM
oxidation speed PMcs on the wall surface of the filter 32 in the radial direction
of the filter 32.
[0047] Thus, in step S300, a ratio of the wall surface deposition amount of the ashes to
the ash deposition amount Asm is first obtained. It should be noted herein that the
ashes deposited on the wall surface of the filter 32 in the radial direction of the
filter 32 are separated from the wall surface due to fluctuations in the exhaust gas
flow rate, and are collected again on the bottom face of the filter 32 that is located
in the downstream side portion of the filter 32 with respect to the flow of exhaust
gas. Accordingly, as the fluctuation amount EXh of the exhaust gas flow rate increases,
the amount of the ashes separated from the wall surface of the filter 32 in the radial
direction of the filter 32 increases, and the deposition amount of the ashes remaining
on the wall surface decreases. Thus, as shown in FIG. 5, the wall surface deposition
ratio R is set to decrease as the fluctuation amount EXh of the exhaust gas flow rate
increases.
[0048] Further, as described above, the ashes deposited on the wall surface of the filter
32 in the radial direction of the filter 32 are separated from the wall surface due
to fluctuations in the exhaust gas flow rate, and are collected again on the bottom
face of filter 32 that is located in the downstream side portion of the filter 32
with respect to the flow of exhaust gas. Accordingly, as the number N of times of
fluctuation in the exhaust gas flow rate increases, the amount of the ashes separated
from the wall surface of the filter 32 in the radial direction of the filter 32 increases,
and the deposition amount of the ashes remaining on the wall surface decreases. Thus,
as shown above in FIG. 5, the wall surface deposition ratio R is set to decrease as
the number N of times of fluctuation in the exhaust gas flow rate increases.
[0049] In this manner, the wall surface deposition ratio R is variably set on the basis
of the fluctuation amount EXh of the exhaust gas flow rate and the number N of times
of fluctuation. Subsequently, the ash thickness At, which is a thickness of the ashes
deposited on the wall surface of the filter 32 in the radial direction of the filter
32, is calculated on the basis of the ash deposition amount Asm, the wall surface
deposition ratio R, the deposition density Ad, and a collection area S for the PM
in the radial direction of the filter 32 (that is, the collection area S on the wall
surface of the filter 32 in the radial direction of the filter 32) (S400). In this
case, since there is established a relational expression, the density of the ashes
= the deposition amount of the ashes / (the collection area for the ashes × the thickness
of the ashes), the ash thickness At is calculated on the basis of an expression (2)
shown below, which is obtained by transforming the relational expression.

In the expression (2), At denotes an ash thickness (mm), Asm denotes an ash deposition
amount (g), R denotes a wall surface deposition ratio, (AsmxR) denotes a total amount
(g) of the ashes deposited on the wall surface of the filter 32 in the radial direction
of the filter 32, Ad denotes a deposition density (g/mm
3) of the ashes, and S denotes a collection area (mm
2) for the PM in the radial direction of the filter 32.
[0050] Subsequently, the PM oxidation speed PMcs is calculated on the basis of the ash thickness
At and the bed temperature T of the filter 32 (S500). It should be noted that the
bed temperature T is estimated from the aforementioned exhaust gas temperature TE,
which indicates a temperature of the exhaust gas flowing into the filter 32. Then
in this step S500, an oxidation speed map shown in FIG. 6 is referred to. On the basis
of this oxidation speed map, the PM oxidation speed PMcs is calculated to increase
as the bed temperature T rises. Further, until the value of the ash thickness At reaches
a predetermined value, the PM oxidation speed PMcs is calculated to decrease as the
ash thickness At increases. Then, when the value of the ash thickness At exceeds the
predetermined value described above, the PM oxidation speed PMcs is fixed to a certain
value regardless of the value of the ash thickness At.
[0051] When the PM oxidation speed PMcs is thus calculated, the present processing is ended.
Then, the PM deposition amount PMsm is estimated according to the aforementioned expression
(1), through the use of the PM oxidation speed PMcs calculated in the present processing.
[0052] Next, the advantageous effects of this embodiment of the invention will be described.
As described above, in this embodiment of the invention, based on the knowledge of
the inventor, the PM oxidation speed PMcs is set on the basis of the deposition thickness
of the ashes (the ash thickness At) that affects the oxidation speed of the PM. Thus,
the PM oxidation speed PMcs can be accurately calculated. When the accuracy of the
PM oxidation speed PMcs is enhanced, the accuracy in estimating the PM deposition
amount PMsm according to the aforementioned expression (1) is also enhanced. Due to
the enhancement of the accuracy in estimating the PM deposition amount PMsm, the timing
for ending the recovery process is made appropriate. Therefore, it is possible to
reduce the possibility that there are burned embers of the PM when the recovery process
is completed.
[0053] Further, the ashes deposited in the filter 32 are compressed due to the impetus of
flowing exhaust gas. Therefore, the density of the ashes deposited in the filter 32,
namely, the deposition density of the ashes can be calculated on the basis of the
maximum flow rate of exhaust gas. Thus, the deposition density Ad of the ashes is
calculated on the basis of the maximum flow rate EXmax of exhaust gas. Then, the deposition
amount of the ashes is divided by a value that is obtained by multiplying the deposition
density Ad by the collection area of the filter 32, so that the thickness of the ashes
deposited in the filter 32 can be calculated. In this case, in particular, the wall
surface deposition amount, which is the amount of the ashes deposited on the wall
surface of the filter 32 in the radial direction of the filter 32, is calculated,
and the collection area S of the filter 32 in the radial direction of the filter 32
is set as the collection area. Therefore, the thickness of the ashes deposited on
the wall surface of the filter 32 in the radial direction of the filter 32 can be
calculated. Then, the PM oxidation speed PMcs is set on the basis of the thickness
of the ashes deposited on the wall surface of the filter 32 in the radial direction
of the filter 32. Therefore, the PM oxidation speed PMcs on the wall surface of the
filter 32 in the radial direction of the filter 32 can be accurately calculated.
[0054] Further, the ashes deposited on the wall surface of the filter 32 in the radial direction
of the filter 32 are separated from the wall surface due to fluctuations in the exhaust
gas flow rate, and are collected again on the bottom face of the filter 32 that is
located in the downstream side portion of the filter 32 with respect to the flow of
exhaust gas. Accordingly, as the fluctuation amount of the exhaust gas flow rate increases,
the amount of the ashes separated from the wall surface of the filter 32 in the radial
direction of the filter 32 increases, and the deposition amount of the ashes remaining
on the wall surface decreases. Thus, the aforementioned wall surface deposition ratio
R is calculated to decrease as the fluctuation amount of the exhaust gas flow rate
increases. Accordingly, the wall surface deposition amount of the ashes can be appropriately
estimated.
[0055] Further, as the number of times of fluctuation in the exhaust gas flow rate increases,
the amount of the ashes separated from the wall surface of the filter 32 in the radial
direction of the filter 32 increases, and the deposition amount of the ashes remaining
on the wall surface decreases. Thus, the number of times that the fluctuation amount
EXh of the exhaust gas flow rate becomes larger than a predetermined value is measured,
and the aforementioned wall surface deposition ratio R is calculated to decrease as
the measured number of times increases. Accordingly, in this manner as well, the wall
surface deposition amount of the ashes can be appropriately estimated.
[0056] As described above, the following advantageous effects can be obtained according
to this embodiment of the invention. (1) The PM oxidation speed PMcs in the filter
32 is calculated on the basis of the thickness of the ashes deposited in the filter
32. In other words, in the recovery process for the filter 32, the PM oxidation speed
PMcs is set on the basis of the thickness of the ashes deposited in the filter 32.
More specifically, the PM oxidation speed PMcs is calculated to decrease as the thickness
of the ashes deposited in the filter 32 increases. In other words, in the recovery
process for the filter 32, the PM oxidation speed PMcs is variably set to decrease
as the thickness of the ashes deposited in the filter 32 increases. Therefore, the
PM oxidation speed PMcs in the filter 32 can be more accurately calculated.
[0057] (2) Because the PM oxidation speed PMcs is accurately calculated, the accuracy in
estimating the PM deposition amount PMsm is enhanced. Therefore, it is possible to
reduce the possibility that there are burned embers of the PM when the recovery process
is completed.
[0058] (3) The ash deposition amount Asm in the filter 32 is calculated, the deposition
density Ad of the ashes is calculated on the basis of the maximum flow rate EXmax
of exhaust gas, and the ash deposition amount Asm is divided by a value that is obtained
by multiplying the collection area of the filter 32 by the deposition density Ad.
Therefore, the thickness of the ashes deposited in the filter 32 (the ash thickness
At) can be calculated. In particular, the wall surface deposition amount, which is
the amount of the ashes deposited on the wall surface of the filter 32 in the radial
direction of the filter 32, is calculated by multiplying the ash deposition amount
Asm by the wall surface deposition ratio R, and the collection area S of the filter
32 in the radial direction of the filter 32 is set as the collection area of the filter
32. Therefore, the ash thickness At on the wall surface of the filter 32 on which
a larger amount of PM is collected can be calculated. Thus, the PM oxidation speed
PMcs on the wall surface of the filter 32 in the radial direction of the filter 32
can be accurately calculated.
[0059] (4) The wall surface deposition ratio R of ashes is set to decrease as the fluctuation
amount EXh of the exhaust gas flow rate increases. Thus, the wall surface deposition
amount of ashes is calculated to decrease as the fluctuation amount EXh of the exhaust
gas flow rate increases. Accordingly, the wall surface deposition amount of ashes
can be appropriately estimated.
[0060] (5) The number N of times of fluctuation, which is the number of times that the fluctuation
amount EXh of the exhaust gas flow rate becomes larger than the predetermined value,
is measured, and the wall surface deposition ratio R of ashes is set to a value that
decreases as the measured number N of times of fluctuation increases. Thus, the wall
surface deposition amount of ashes is calculated to decrease as the number N of times
of fluctuation in the exhaust gas flow rate increases. Accordingly, in this manner
as well, the wall surface deposition amount of ashes can be appropriately estimated.
[0061] It should be noted that the foregoing embodiment of the invention can also be implemented
after being modified as follows. The aforementioned ashes originate from a lubricating
oil for the engine 1, and the ash deposition amount Asm tends to increase as the consumption
amount of the lubricating oil increases. Thus, the ash deposition amount Asm may be
calculated on the basis of the consumption amount of the lubricating oil. It should
be noted that the consumption amount of the lubricating oil can be determined by detecting
the amount of the lubricating oil in an oil pan of the engine 1. Further, as the total
running distance of the vehicle increases, the amount of the lubricating oil that
has been consumed up to that time also increases. Therefore, the consumption amount
of the lubricating oil can also be estimated on the basis of the total running distance
of the vehicle. Further, as the total operating time of the internal combustion engine
increases, the amount of the lubricating oil that has been consumed up to that time
also increases. Therefore, the consumption amount of the lubricating oil can also
be estimated on the basis of the total operating time of the internal combustion engine,
or the accumulated value of the fuel injection amount, which is correlated with the
total operating time. In the case where the ash deposition amount Asm is calculated
on the basis of the consumption amount of the lubricating oil as in this modified
example, the ash deposition amount Asm is calculated to increase as the consumption
amount increases. As a result, the ash deposition amount Asm can be appropriately
calculated.
[0062] The wall surface deposition ratio R is set on the basis of the fluctuation amount
EXh of the exhaust gas flow rate and the number N of times of fluctuation in the exhaust
gas flow rate. However, the wall surface deposition ratio R may be set on the basis
of the fluctuation amount EXh of the exhaust gas flow rate alone or the number N of
times of fluctuation in the exhaust gas flow rate alone.
[0063] The ash thickness At on the wall surface of the filter 32 in the radial direction
of the filter 32 is obtained. Also, the ash thickness At on the bottom face of the
filter 32, which is located in the downstream side portion of the filter 32 with respect
to the flow of exhaust gas, may be obtained, and the PM oxidation speed PMcs on the
bottom face may be obtained on the basis of the map shown above in FIG. 6 or the like.
In this modification example, the area of the bottom face of the filter 32, which
is located in the downstream side portion of the filter 32 with respect to the flow
of exhaust gas, may be set as the collection area S in the aforementioned expression
(2), and the ash thickness At on the bottom face may be calculated on the basis of
an expression (3) shown below, which is obtained by transforming part of the expression
(2).

In the expression (3), At denotes an ash thickness (mm) on the bottom face, Asm denotes
an ash deposition amount (g), R denotes a wall surface deposition ratio, Asm×(1-R)
denotes a total amount (g) of the ashes deposited on the bottom face of the filter
32, Ad denotes a deposition density (g/mm
3) of ashes, and S denotes a collection area (mm
2) for the PM on the bottom face of the filter 32. According to this modification example,
the accuracy in estimating the PM oxidation speed PMcs on the bottom face of the filter
32 can be enhanced.
[0064] In the foregoing embodiment of the invention, the ash thickness At on the wall surface
of the filter 32 in the radial direction of the filter 32 is obtained. However, an
average of the ash thickness At in the filter 32 may be obtained, and the average
PM oxidation speed PMcs in the filter 32 may be obtained on the basis of that average
and the map shown above in FIG. 6 or the like. In this modification example, an entire
collection area of the filter 32 may be set as the collection area S in the aforementioned
expression (2), and an average of the ash thickness At in the filter 32 may be calculated
on the basis of an expression (4) shown below, which is obtained by transforming part
of the expression (2).

In the expression (4), At denotes an average (mm) of the ash thickness, Asm denotes
an ash deposition amount (g), Ad denotes a deposition density (g/mm
3) of ashes, and S denotes an entire collection area (mm
2) for the PM in the filter 32.
[0065] Fuel for heating up the filter 32 is supplied from the fuel addition valve 5. Also,
the filter 32 may be heated up by carrying out post injection (fuel injection that
is carried out again at a timing later than a timing at which main injection is carried
out) by the fuel injection valves 4a to 4d. Further, the supply of fuel by the fuel
addition valve 5 and the supply of fuel through post injection may be performed in
a compatible manner.
[0066] The aforementioned addition agent is fuel for the engine 1. However, any addition
agent may be used as long as a similar effect can be obtained. The number of catalysts
or filters disposed in the converter 30 can be arbitrarily set. For example, the invention
is also applicable in the same manner to an exhaust gas control apparatus which includes
the filter 32 and does not include the oxidation catalyst 31, and in which the temperature
of the filter 32 is raised by oxidizing the fuel on the filter 32.
[0067] The aforementioned engine 1 is an inline four-cylinder internal combustion engine.
However, the invention is also applicable in the same manner to an exhaust gas control
apparatus for an internal combustion engine that includes one, two, three, five or
more cylinders or has its cylinders arranged in a different manner.
1. An exhaust gas control apparatus for an internal combustion engine,
characterized by comprising:
a filter (32) that collects particulate matter in exhaust gas; and
a control device (25) that performs a recovery process for the filter (32), wherein
the control device (25) calculates an oxidation speed of the particulate matter in
the filter (32) on a basis of a thickness of ashes deposited in the filter (32).
2. The exhaust gas control apparatus according to claim 1, wherein the control device
(25) calculates the oxidation speed in a manner such that the oxidation speed is decreased
as the thickness of the ashes deposited in the filter (32) increases.
3. The exhaust gas control apparatus according to claim 1 or 2, wherein the control device
(25) calculates the thickness of the ashes deposited in the filter (32) by calculating
a deposition amount of the ashes in the filter (32), calculating a deposition density
of the ashes on a basis of a maximum flow rate of exhaust gas, and dividing the deposition
amount by a value that is obtained by multiplying a collection area of the filter
(32) by the deposition density.
4. The exhaust gas control apparatus according to claim 3, wherein the control device
(25) calculates a wall surface deposition amount that is an amount of ashes deposited
on a wall surface of the filter (32) in a radial direction of the filter (32), as
the deposition amount of the ashes, and sets a collection area of the filter (32)
in the radial direction of the filter (32), as the collection area.
5. The exhaust gas control apparatus according to claim 4, wherein the control device
(25) calculates the wall surface deposition amount in a manner such that the wall
surface deposition amount is decreased as a fluctuation amount of an exhaust gas flow
rate increases.
6. The exhaust gas control apparatus according to claim 4, wherein the control device
(25) measures the number of times that a fluctuation amount of an exhaust gas flow
rate becomes larger than a predetermined value, and calculates the wall surface deposition
amount in a manner such that the wall surface deposition amount is decreased as the
measured number of times increases.
7. The exhaust gas control apparatus according to any one of claims 4 to 6, wherein the
control device (25) calculates a ratio of the amount of the ashes deposited on the
wall surface to a total deposition amount of the ashes in the filter (32), and calculates
the wall surface deposition amount on a basis of the calculated ratio.
8. The exhaust gas control apparatus according to any one of claims 1 to 7, wherein the
control device (25) calculates the oxidation speed of the particulate matter on a
basis of the thickness of the ashes deposited in the filter (32) and a bed temperature
of the filter (32).
9. The exhaust gas control apparatus according to any one of claims 1 to 8, wherein the
control device (25) calculates a deposition amount of the particulate matter in the
filter (32) using the calculated oxidation speed during the recovery process, and
ends the recovery process when the calculated deposition amount of the particulate
matter becomes smaller than a predetermined recovery end value.
10. A control method for an exhaust gas control apparatus for an internal combustion engine,
the exhaust gas control apparatus including a filter (32) that collects particulate
matter in exhaust gas,
characterized by comprising:
calculating an oxidation speed of the particulate matter in the filter (32) on a basis
of a thickness of ashes deposited in the filter (32); and
performing a recovery process for the filter (32) using the calculated oxidation speed.
11. The control method according to claim 10, wherein the oxidation speed is calculated
to decrease as the thickness of the ashes deposited in the filter (32) increases.
12. The control method according to claim 10 or 11, wherein a deposition amount of the
particulate matter in the filter (32) is calculated using the calculated oxidation
speed during the recovery process, and the recovery process is ended when the calculated
deposition amount of the particulate matter becomes smaller than a predetermined recovery
end value.